Systems and methods for nasal irrigation

ABSTRACT

Systems and methods for nasal irrigation are provided in which a nasal irrigation device includes a source of saline solution, an effluent receptacle, a nasal interface, a vacuum source, a fluid passageway to communicate the source of saline solution with the effluent receptacle through the nasal interface and a nasal cavity of the user, and a switch and valve assembly for selectively controlling the vacuum source and flow of the saline solution through the fluid passageway. The saline solution source bottle is disposed relative to the device to provide gravitational inducement of saline solution to the nasal interface in engagement to the device user&#39;s nostrils. A combination of the gravitational inducement and the relative vacuum from an effluent receptacle generates a fluid flow for irrigating, cleansing and massaging the nasal cavity and ostia of a user. The entire device is assembled as a hand-held device for convenient lifting and disposal against the user&#39;s nostrils.

This application is a continuation of U.S. patent application Ser. No.15/989,663, filed May 25, 2018, now U.S. Pat. No. //insert later//,which is a continuation of U.S. patent application Ser. No. 13/276,448,filed Oct. 19, 2011, now U.S. Pat. No. 9,999,567, which is acontinuation of U.S. patent application Ser. No. 12/042,906, filed Mar.5, 2008, now U.S. Pat. No. 8,048,023, which claimed the benefit of U.S.Provisional Patent Application Ser. No. 60/895,180, filed Mar. 16, 2007,and U.S. Provisional Patent Application Ser. No. 60/893,191, filed Mar.6, 2007, the disclosures of which are incorporated herein by reference.

TECHNICAL FIELD

The presently disclosed embodiments generally relate to methods anddevices for irrigating and rinsing the nasal cavity and anatomicalopenings thereto.

BACKGROUND

Nasal and sinus disease and sinus related syndromes and symptoms are acommon clinical problem with considerable patient morbidity, substantialdirect costs, and a significant, negative impact on the quality of lifefor those who are afflicted. The four primary categories of afflictedgroups are: 1) individuals with acute and chronic rhinosinusitis; 2)individuals with acute upper respiratory infections, 3) individuals whosuffer from allergic rhinitis; and 4) individuals with chronic snoringproblems. These four categories amount to millions of people who sufferfrom nasal congestion on a daily basis.

The Centers for Disease Control and Prevention estimated the number ofcases of chronic rhinosinusitis in the United States to be 35 million in1994, a prevalence of about 13.5%, or about 40.5 million Americansadjusted for 2007 population figures (estimates from the National HealthInterview Survey, 1994. Vital Health Stat 10. 1995:261-520.)Rhinosinusitis was the fifth most common diagnosis for which antibioticswere prescribed from 1985 to 1992 (McCaig L F, Hughes J M. Trends inantimicrobial drug prescribing among office-based physicians in theUnited States. JAMA. 1995; 273:214-219). In 1996 rhinitis accounted forapproximately 26.7 million office and emergency department visitsresulting in $5.8 billion in direct costs (Ray N F, Baraniuk J N, ThamerM, et al. Healthcare expenditures for sinusitis in 1996: contributionsof asthma, rhinitis, and other airway disorders. J Allergy Clin Immunol.1999; 103:408-414).

Allergic rhinitis has been reported to affect approximately 17% of thegeneral population in the United States (Ray N F, Baraniuk J N, ThamerM, et al. Healthcare expenditures for sinusitis in 1996: contributionsof asthma, rhinitis, and other airway disorders. J Allergy Clin Immunol.1999; 103:408-414), and in selected pediatric populations might bepresent in up to 42% (Wright A L, Holberg C J, Martinez F D, Halonen M,Morgan W, Taussig L M. Epidemiology of physician-diagnosed allergicrhinitis in childhood. Pediatrics 1994; 94:895-901). This amounts to anupper estimate of 60 million Americans.

According to the National Sleep Foundation, snoring currently affectsapproximately 90 million American adults, 37 million on a regular basis.

The combined number of those who suffer from rhinosinusitis, allergicrhinitis, and snoring amounts to a high estimate of 190 millionAmericans and a low estimate of 128 million Americans, not accountingfor double-counting individuals who may be in two or more categories.Adopting the conservative assumption of over 40% duplication yields anestimate of 75 million Americans who suffer from adverse sinus symptomsand would benefit from an effective therapy to relieve those symptoms.

Bathing the nasal and sinus cavities with lightly-salted water to washaway encrusted mucous, irritants, and foreign particles for the purposeof improving airflow and relieving nasal congestion has been widelypracticed across many cultures for literally thousands of years. Morerecently, and particularly since about 1990, a significant number ofpeer-reviewed clinical trials have been undertaken at leading Americanand European medical schools and research centers testing whether theanecdotal claims of relief from the symptoms of nasal maladies as aresult of nasal irrigation, are well founded and pass scientificscrutiny. (Harvey R, Hannan S A, Badia L, Scadding G. Nasal salineirrigations for the symptoms of chronic rhinosinusitis. CochraneDatabase of Systematic Reviews 2007, Issue 3. Art No.: CD006394. DOI:10.1002/14651858.CD006394.pub2.)

Several clinical studies demonstrate that regular use of nasalirrigation is an effective therapy to relieve the symptoms of chronicand acute rhinosinusitis, including statistically significant findingsof reduced nasal congestion, increased nasal passage airflow, reduceddoctor visits, reduced number of prescriptions for sinus medicine, andimproved quality of life. (Rabago D, Zgierska A, Mundt M, et al.Efficacy of daily hypertonic saline nasal irrigation among patients withsinusitis: A randomized controlled trial. Journal of Family Practice.2002;51(12):1049-1055.) Other clinical studies indicate that regularnasal irrigation is a beneficial therapy for the treatment ofallergy-related nasal symptoms. (Garavello W, Romagnoli M, Sordo L, etal. Hypersaline nasal irrigation in children with symptomatic seasonalallergic rhinitis: a randomized study. Pediatric allergy and immunology.2003;14:140-143.) Other as yet unpublished clinical studies arecurrently underway, testing whether nasal irrigation is an effectivepreventive therapy with respect to the common cold and snoring.

These studies indicate that nasal irrigation is a clinically provenmethod for treating the symptoms of sinus-related disease by exposingthe nasal cavity to a streaming volume of saline. While the exactmechanism by which nasal irrigation's effectiveness is achieved is notyet well understood by the medical and scientific research community, itis likely multifaceted and includes a number of physiological effectswhich individually or in concert may result in an improved ability ofthe nasal mucosa to reduce the pathologic effects of inflammatorymediators and other triggers of allergic rhinitis, asthma and otherchronic mucosal reactions, as follows. First, it rinses the entireinterior of the nasal cavity, washing away encrustations that may beblocking the multiple ostia that connect the sinus cavities to the nasalcavity, thereby allowing the sinus cavities to properly drain into thenasal cavity and making the sinus cavities a much less attractivebreeding ground for the colonization of bacteria. Second, it decreasesthe viscosity of the mucous in the nasal cavity, thereby greatlyreducing the formation of interior encrustations. Third, it leaves asmall residue of saline on the interior surfaces of the nasal cavity,including the openings to the sinus cavities and sometimes in the sinuscavities themselves. This is beneficial because saline has an inherentlyantiseptic quality that hinders the growth of bacteria. Fourth, exposureof the turbinates, vascular tissue that warms and humidifies the airinspired through the nose before it reaches the lungs, to saline causesthem to reduce in size, thereby reducing nasal congestion. Fifth, itimproves mucociliary clearance as a result of increased ciliary beatfrequency, which improves the ability of the mucosa to perform itsnatural, flushing function. Sixth, the saline may wash away airbornebacteria, viral particles, irritants and other foreign particles thatcause infections and allergies. (See: Ponikau J U, Sherris D A, KephartD M, et al. Striking deposition of toxic eosinophilic major basicprotein in mucus: Implications for chronic rhinosinusitis. J AllergyClin Immunol. 2005; 116(2):362-369.; Ozsoylu S. Nose drops and thecommon cold. Eur J Pediatr. 1985;144:294.; Karadag A. Nasal saline foracute sinusitis. Pediatrics. 2002;109:165.; Kurtaran H, Karadag A, CatalF, et al. A reappraisal of nasal saline solution use in chronicsinusitis. Chest. 2003;124:2036-2037.; Georgitis J W. Nasal hyperthermiaand simple irrigation for perennial rhinitis. Changes in inflammatorymediators. Chest. 1994;106:1487-1492.; Talbot A R, Herr T M, Parsons DS. Mucocilliary clearance and buffered hypertonic saline solution.Laryngoscope. 1997;107:500-503.; Boek W M, Graamans K, Natzijl H, et al.Nasal mucociliary transport: New evidence for a key role of ciliary beatfrequency. Laryngoscope. 2002;112:570-573.)

There are three methods by which the nasal cavity can be irrigated:gravity, pressure, and suction.

Gravity-based devices allow the flow of saline into the nasal cavity by,for example, inserting the tip of a teapot-like spout into one nostriland pouring the saline into it. The saline then flows around theposterior margin of the nasal septum and out the other nostril of theuser. An example of a gravity-based device is the neti pot. However, theawkward physical position required to accomplish such a rinse isdifficult for many people, and the free flowing effluent from the nasalpassageway is messy so that substantial clean up procedures arenecessary.

Pressure-based devices pump the saline into the nasal cavity, again, byintroducing the saline into one nostril, forcing it under pressurearound the posterior margin of the nasal septum, and allowing it todrain out the other nostril. This can be done, for example, by placingthe nozzle of a saline-filled, flexible plastic tube or bottle into onenostril and squeezing it, thereby injecting the saline into one nostril,through the nasal cavity, and out the other nostril. Although thisavoids some of the physical awkwardness needed to achieve a gravityforced flow, the problems of messiness and the attendant inconvenienceof cleaning remain. In addition, the varied pressures imparted by asqueeze tube can impart undesired, painful, and even harmful pressuresthroughout the nasal passageway, and particularly on the Eustachian tubeostia. Thus, this requires some acquired skill for proper use.

Prior devices have generally not utilized suction. The most commonmethod by which suction is used to perform nasal irrigation is as simpleas the user cupping a small amount of lightly salted water in his palmand sniffing it into his nostrils.

There is presently no practical device that offers a user the ability topractice nasal irrigation using all three delivery methods in a singledevice.

There is presently no practical device that offers a user the ability topractice nasal irrigation in a combination of either gravity andpressure, gravity and suction, or pressure and suction in a singledevice, nor is there a device that offers a powered mechanism in any ofthe three foregoing combinations.

There is presently no practical device that offers a user the ability topractice nasal irrigation using suction alone.

There is a need for a convenient hand-held device that can safelyirrigate the nasal cavity with a controlled, gentle supply, draw theirrigant through the nasal cavity under the influence of gentle poweredsuction, collect the effluent safely in a manner facilitating quick andeasy disposal, and is readily adaptable to a wide variety of nasaldimensions.

SUMMARY

A nasal irrigation device is provided for therapeutic irrigating of anasal cavity of a user. The device includes a source of saline solution,an effluent receptacle, a nasal interface, a vacuum source, fluidpassageways and a switch and valve assembly. The nasal interface engagesa device user's nostrils to deliver saline solution by gravity from thesource to the nasal cavity. The source of saline solution communicateswith the effluent receptacle through the fluid passageway, the nasalinterface, and the device user's nasal cavity. The switch and valveassembly controls the vacuum source and flow of saline solution throughthe fluid passageway. It is understood that in addition to theaforementioned saline solution, alternative irrigants may also beincorporated into use with the device.

In accordance with another aspect of the present embodiments, a pressuresource forms a relative pressure in the source of saline solution tosupplement or replace gravitational inducement of the solution towardsthe interface.

In yet another embodiment, the nasal irrigation device comprises ahand-held assembly including the saline solution source, the effluentreceptacle, the nasal interface, the vacuum source, the fluid passagewayand the switch. A power source such as a battery pack controls thesupply of energy to an electric motor and pump assembly functioning asthe vacuum source.

Yet another embodiment comprises a hand-held nasal irrigation deviceincluding the source of saline solution, the effluent receptacle, thenasal interface, the fluid passageway and a valve for selectivelycontrolling the flow of the saline solution through the fluid passagewaywherein the effluent receptacle is disposed relative to the source andthe nasal interface for gravitational inducement of the saline solutionthrough the device. Neither a vacuum source nor a pressure source isincluded in this embodiment, as gravity is the sole source of inducementof the saline solution through the device and the nasal cavity.

A method for irrigating a nasal cavity is also provided includingsealing the nares of a user to a hand-held device including anassociated fluid passageway in communication with a saline solutionsource and a saline effluent receptacle. The passageway, source andreceptacle are integrally assembled in the hand-held device. A relativevacuum is applied to the effluent receptacle with a powered suctionsource also included in the hand-held device. The saline solution isreleased from the source into the passageway and the nasal cavitywhereby a flow of the saline through the nares and around a posteriormargin of a nasal septum of the user irrigates the nasal cavity.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view of an embodiment of the subject nasalirrigation device;

FIG. 2 is a side elevational view of the embodiment of FIG. 1 ;

FIG. 3 is a sectional perspective view showing a top wall removed for aclearer viewing of the housed elements of the assembly of the embodimentof FIG. 1 ;

FIG. 4 is a partial cross-sectional view of the side elevation view ofFIG. 2 wherein an outer sidewall is removed, again for showing internalelements;

FIG. 5 is top plane view of the device corresponding to FIG. 3 whereinthe top wall is also removed to similarly illustrate internalcomponents;

FIG. 6 is a partial view of the device internal components wherein allouter walls have been removed;

FIG. 7 is a view similar to FIG. 6 of an alternative embodiment whereina vacuum source such as an electric pump assembly is lacking;

FIG. 8 is a perspective view of another alternative embodiment wherein ahandle is disposed below a nasal interface, forward of an effluentreceptacle;

FIG. 9 is another alternative embodiment wherein both the source ofsaline solution, and the effluent receptacle are relatively disposedbelow the nasal interface;

FIG. 10 is a perspective view of yet another alternative embodimentincluding a mug-like configuration including a side handle;

FIG. 11 is a elevated side view of the embodiment of FIG. 10particularly illustrating a back view not evident from FIG. 10 ;

FIG. 12 is a partial cross-section view of the embodiment of FIG. 11particularly illustrating internal componentry; and

FIG. 13 is a flowchart illustrating steps of an embodiment forpracticing a method for nasal irrigating.

BRIEF DESCRIPTION

The Figures show a nasal irrigation device or tool, preferably easilyhand-held in use, which provides a more convenient, cleaner, morepleasant, and more effective irrigating therapy for the nasal cavity andsinus ostia. The device 10 is principally comprised of three components,an irrigant source bottle 12, containing, for example, saline solution,a receptacle bottle 14 for receiving saline effluent, and a controller16 for controlling the communication of fluid from the first bottle,through the nasal cavity and into the second bottle as will behereinafter more fully explained. The bottles 12,14 may be of any of avariety of shapes and may be attached to the controller in any varietyof manners, such as with a threaded neck, a pinch fit, a bayonet mount,or the like. A typical size will accommodate 6 to 10 ounces of fluid. Itis envisioned that the first bottle 12, upon being emptied as the resultof having been used, can subsequently be used as the second bottle 14which upon being filled with effluent by use can then be thrown away.Accordingly, the provision of a single bottle provides both the firstbottle of saline source at one time, and then the effluent receptacle 14at a next time. It is also within the intended scope of the presentembodiments that the bottles may be refillable, or reusable, or may evenbe permanent chambers within the controller 16 that may be filled oremptied upon completion of an irrigating therapy. In FIG. 3 , bottle 12′lacks a top wall such that it is open ended for refilling. Althoughsaline solution is mentioned here as the exemplary irrigant, theembodiments are intended to include alternate irrigants of a variety ofsaline mixes including flavorants or medicines.

The controller 16 includes a handle portion 20 and a housing 22. Thehandle 20 is intended to function as a pistol-type grip including atrigger 24 and a pedestal base 26 having a flat bottom wall 28 to allowthe entire assembly 10 to stand upright on a flat surface such as abathroom vanity or kitchen countertop when not in use. The base 26 alsoincludes an arcuate cutout 30 shaped to match a contour of the effluentbottle 14 in a manner to facilitate support and positioning of thebottle 14 relative to the controller 16. The handle assembly 20 isconfigured to accommodate either a right-handed or left-handed grip asthe trigger 24 and the ergonomic configuration of the handle areintended to be handed-neutral. The housing 22 includes a top cover 34including a source bottle opening 36 through which the saline sourcebottle extends and a nasal interface 38 disposed to engage the nares(nostrils) 32 of a user's nose with a good seal for forming an integralfluid passageway between the source bottle 12 and the effluent bottle 14through a user's nasal cavity. The nasal interface is comprised of firstand second nozzles 40, 42, which are also called nasal cushions, andwhich can swivel or pivot as may be necessary to form a cushioned sealagainst the nares, depending upon the personal anatomy of the user. Apositive seal between the nasal cushions and a user's nares is essentialto the successful operation of the device with respect to both itstherapeutic function as well as to its distinguishing qualities ofconvenience, cleanliness and neatness. Therefore, the cushions 40, 42are especially configured to facilitate such a seal. In operation,leakage from the nasal cavity is precluded so long as the engaging sealbetween the interface 38 and nostrils is maintained. It can be seen thatthe nasal cushions have a truncated elliptical configuration in a planeview and with a somewhat flattened conical configuration in crosssection. The cushion opening is slightly spaced from the middle of thecushion to provide a more extended sealing surface for engaging theouter edges of the nares than the inner edges that are bordered by thenose columella. The cushions 40, 42 may alternatively comprise communalnozzles that are easily removable and replaceable for convenient washingor for the attachment of a personal set of nozzles corresponding todistinct individual users. Adjustment to accommodate different nosesizes is accomplished by rotating supporting swivel gears 56 or by othergenerally understood mechanical means.

The overall configuration of a nasal interface is intended to achieve apositive, fluid-tight seal upon gentle but firm urging of the nozzles40, 42 against the nares 32 of a user.

With particular reference to FIGS. 3-6 , it can be seen that the housingalso includes a lower housing wall 44 intended to support the fluidconduits forming the fluid passageway and a pump assembly 60 fordirecting the saline from the first bottle 12 to the second bottle 14.The first bottle is mounted to the controller 16 so that saline may becommunicated to a saline supply conduit 46 and a supply bottle pressurerelief conduit 48 (FIG. 6 ). The supply conduit passes through trigger24 which may crimp the conduit or otherwise stop the flow of fluidthrough the conduit such as with a valve (not shown). The conduit 46 isnormally closed by the crimp and will only communicate fluid from thebottle to a nasal interface upon the user activating the trigger 24. Thesupply conduit 46 directly communicates with first nozzle 40 so that thesaline may be directed to the left nostril (as shown) of the user, passthrough the nasal cavity and then be received in the second nozzle 42for direct communication into the effluent bottle 14 through effluentconduit 50. Effluent bottle 14 is mounted to effluent bottle mount 52.The size and configuration of the conduits are not particularly limitedother than to permit ready fluid flow. Sizes of 3/16 to 5/16 of an inchhave proven operative. Minimizing the sharpness of conduit angle termsand appropriate volume metrics achieve the desired irrigating therapy.The effluent conduit 50 terminates in an effluent bottle mount 52 whichprovides air-tight and fluid-tight seals between the effluent bottle 14,conduit 50, and vacuum source conduit 54.

It is a feature of the embodiments that the vacuum pump assembly 60 is asource of relative vacuum within the device 10 to better facilitate theirrigating therapy by enhancing the flow with a suction force drawingthe saline irrigant through the nasal cavity in addition to the gravityinducement of flow from the source bottle 12. It is believed that avacuum source is an improved urging force relative to a user's healthand therapeutic experience as opposed to pressure based pump deviceswhich push the saline into the cavity and develop high pressure regionstherein. Accordingly, vacuum pump 60 communicates the relative vacuum ornegative pressure to the effluent bottle through the vacuum conduit 54thereby facilitating drawing the saline through the nasal cavity and outthe second nasal cushion 42. A pressure relief valve 64 is disposed suchto limit the maximum amount of vacuum to not more than about 5.5 inchesof mercury. Pressure relief valve 62 similarly permits air to replacethe saline flowing out of supply bottle 12.

Electrical power is supplied to the pump 60 from a battery source 68located in the handle base 26. The battery source may comprisereplaceable or rechargeable batteries, or may alternatively comprise acorded power source for irrigating devices that may be continuallyemployed in professional medical settings.

With particular reference to FIG. 4 , the trigger 24 operates to notonly release the flow of saline through the supply conduit 46, but willalso engage a switch 70 upon being pulled closed to supply electricalenergy to the pump 60 from the battery supply 68.

In operation, the device 10 is disposed adjacent to the nostrils in amanner as shown in FIG. 2 , by either being hand-held, or if beingsupported on a surface by moving the user's head to the intendedengagement position. The user will pull the trigger 24 which willcontemporaneously cause several consequences. It can be seen that thefirst bottle 12 is relatively disposed to the nasal cavity so that thesaline is above the nasal cavity. The opening of the saline supplyconduit 46 allows the saline fluid to flow to the first nozzle simply bygravity and similarly through the nasal cavity in the remaining fluidpassageways, all by gravity. The use of the force of gravity alone is infact one particular embodiment as will be discussed below. However,drawing the fluid through the nasal cavity by means of powered suctionsignificantly enhances the washing, massaging, and rinsing elements thatare central to effective nasal irrigation. In addition, the use ofpowered suction virtually eliminates the risk of applying painful andpotentially harmful pressure to the Eustachian tube ostia in the nasalcavity. Since the flow is all downhill, a relatively small amount ofvacuum is required to achieve the desired effect of drawing the salinearound the posterior margin of the nasal septum and out the effluentnaris. A miniature pump that generates vacuum in the range of from 3 to5 PSI is sufficient for the purpose of adequately depressurizing theeffluent bottle. However, an alternative embodiment (FIG. 12 ) mayreadily include a multi-speed pump source for varying the pressure basedupon different trigger positions.

With particular reference to FIG. 7 , an alternative embodiment of afluid passageway 82 is shown in which the pump assembly 60 and batterypack 68 are lacking. Saline would pass through the nasal cavity throughthe supply conduit 46 and to the effluent conduit 50 for flow into theeffluent receptacle merely by gravitational inducement as both the nasalinterface 38 and the effluent receptacle 14 (not shown) are disposeddownhill from the supply bottle 12. Although the flow would lack theenhanced washing action of the powered flow of the embodiment of FIG. 1, the embodiment of FIG. 7 still provides a therapeutic irrigation ofthe nasal cavity. Relieve valves 64, 62 would function more as ventsthan as pressure regulators in this embodiment.

With particular attention to FIG. 8 , an alternative embodiment 90 isshown in which the handle 92 is directly disposed below the nasalinterface 94 and forward of the receptacle bottle 14, and includes athumb switch 95 which operates to release the flow of saline and tosupply electrical energy to the pump. Although the internal conduitscomprising the fluid passageway within this embodiment 90 are slightlydifferent in order to accommodate the alternative positioning of thebottle 14, the effective operation is the same and provides theadvantage of not having to reach around the bottle 14 to grab the handle20 as in the embodiment of FIG. 1 .

With particular reference to FIG. 9 , yet another alternative embodimentis shown similar to the embodiment of FIG. 8 except that the supplybottle 12″ is now disposed below the housing 98 adjacent to the effluentreceptacle bottle 14″. In this embodiment, since the supply bottle 12″is disposed below the interface 100 mere gravity cannot induce a salinesolution from the bottle 12″ to the interface 100. Accordingly, bottle12″ must be pressured in some manner to urge saline through the supplyconduit 102. In this case the pump assembly (not shown) pumps air intothe bottle 12″ via pressure conduit 104 in a manner opposite of thepumping of air out of the effluent receptacle bottle 12″ to achieve thedesired relative vacuum therein. Alternatively, the pump assembly couldcomprise a first pump (not shown) for accomplishing the pressurizing ofthe supply bottle 12″, and a second pump (not shown) to effect therelative vacuum in effluent receptacle 14″ in a manner similar to pump60.

With particular reference to FIGS. 10-12 , an alternative embodiment isshown having more of a mug-like configuration 72 including a side handle74 and a thumb controlled trigger 76 (a nasal interface is not shown). Asupply bottle 78 is received in a support mount 80 while the effluentbottle 81 has a removable chamber 82. Trigger 76 controls a two-speedswitch 77 for variable flow.

With particular reference to FIG. 13 , the method for practicing nasalirrigation is detailed. The method comprises sealing a user's nares to afluid passageway of the device 10 including the supply and effluentconduits. When the user turns the device on by pulling trigger 24, arelative vacuum is applied 108 to effluent receptacle 14 while saline isreleased from the supply bottle 12 to effect flow to the nasal interface38 and into the nasal cavity and specifically around the posteriormargin of a nasal septum and ultimately to the effluent bottle. The flowis induced by gravity as a result of the positioning of the supplybottle 12 above the interface 38 and the receptacle bottle 14 and by thesuction resulting from the relative vacuum in the effluent bottle 14.

The liquid supply should at least comprise a saline solution composed toavoid irritating the cavity. It has been found that a mix comprisingvarious fragrances or tastes may enhance the experience, such aseucalyptus, chamomile, mint, or the like. It has also been found thatbuffering the solution with sodium bi-carbonate may enhance theexperience. It has also been found that the use of hypertonic saline mayenhance the experience. Alternative irrigants may also be used as wellas medicine mixes such as an antibiotic, steroid or analgesics that areespecially suited to nasal cavity delivery as rinses as opposed toabsorbents.

The exemplary embodiments have been described with reference to thepreferred embodiments. Obviously, modifications and alterations willoccur to others upon reading and understanding the preceding detaileddescription. It is intended that the exemplary embodiment be construedas including all such modifications and alterations insofar as they comewithin the scope of the appended claims or the equivalents thereof.

1. A nasal irrigation device, comprising: a source of irrigant; aneffluent receptacle; a housing located between the source of irrigantand the effluent receptacle, the housing including: a vacuum source forapplying a relative vacuum to the effluent receptacle; and a fluidpassageway for communicating the irrigant from the source of irrigant tothe effluent receptacle via a nasal cavity of a device user.
 2. Thenasal irrigation device of claim 1, wherein the effluent receptacle islocated below the source of irrigant;
 3. The nasal irrigation device ofclaim 1, wherein the housing further comprises a valve for stopping flowof irrigant through the fluid passageway
 4. The device of claim 1,wherein the housing further comprises a nasal interface for engaging thenostrils of the device user, the nasal interface being part of the fluidpassageway.
 5. The device of claim 4, wherein the nasal interface isselectively removable from the housing.
 6. The device of claim 4,wherein the nasal interface is located above the effluent receptacle. 7.The device of claim 1, wherein the fluid passageway includes a supplyconduit from the source of irrigant and an effluent conduit to theeffluent receptacle.
 8. The device of claim 1, wherein the housingincludes a top cover with an opening for the source of irrigant and alower housing wall with a mount for the effluent receptacle.
 9. Thedevice of claim 1, wherein the vacuum source comprises a pump assembly.10. The device of claim 9, wherein the pump assembly is battery powered.11. The device of claim 9, wherein a vacuum conduit directs the relativevacuum to the effluent receptacle from the pump assembly.
 12. The deviceof claim 1, wherein the housing further comprises a battery source forpowering the vacuum source.
 13. The device of claim 1, wherein thehousing further comprises a switch for selectively controlling thevacuum source.
 14. The device of claim 1, wherein the source of irrigantand the effluent receptacle are selectively separable from the housing.15. The device of claim 1, including a pressure relief valve associatedwith the effluent receptacle.
 16. The device of claim 1, furthercomprising a pressure relief conduit and a pressure relief valve incommunication with the source of irrigant, which permits air to replacethe irrigant.